Post on 11-Jun-2018
Siemens Protection Devices Limited 3
The 7SR191 Capa devices are numeric protection relays designed for application on shunt connected distribution capacitor banks arranged in all common connection configurations, typically single star, double star, delta or in an H configuration. These relays provide all protection functions required in a single device. Relay versions which can be connected to primary voltage transformers provide additional voltage protection functions and metering. The 7SR191 relays are developed from the proven 7SR11 & 7SR12 Argus family of products providing a familiar product using the latest generation of hardware technology. Housed in a 4U high, size E4 or E6 (Optional IEC61850 model) case, these relays provide protection, monitoring, instrumentation and metering with integrated input and output logic, data logging & fault reports. Communication access to the relay functionality is via a front USB port for local PC connection or rear electrical RS485 port for remote connection & optional IEC61850 communication through two rear Ethernet ports (Electrical or Optical).
Protection 37 Undercurrent/Loss of Supply 46MDT Phase Unbalance 46 Negative Phase Sequence Overcurrent 49 Thermal Overload 50 Instantaneous Overcurrent 50N Instantaneous Earth Fault 50BF Circuit Breaker Fail 51 Time Delayed Overcurrent 51N Time Delayed Derived Earth Fault 59C Overvoltage by Current Integration 60C Capacitor Unbalance Current 87REF High Impedance REF 27/59 Under/Over Voltage 47 Negative Phase Sequence Voltage 59IT Inverse Time Overvoltage 59N Neutral Voltage Displacement 67/50 Directional Instantaneous Overcurrent 67/50N Directional Instantaneous Earth Fault 67/51 Directional Time Delayed Overcurrent 67/51N Directional Time Delayed Earth Fault 81 Under/Over Frequency
Supervision 60CTS CT Supervision 74T/CCS Trip & Close Circuit Supervision 60VTS VT Supervision Control CB Control Reswitch Blocking Features Cold Load Settings Four Settings Groups Password Protection – 2 levels User Programmable Logic User specified voltage, current & thermal protection curves Self Monitoring Circuit Breaker Trip and Maintenance Counter Trip Timers
20 Character x 4 Line Backlit LCD Menu Navigation Keys 9 User Programmable Tri-colour LEDs User Language Configuration
Primary/Secondary Current Phases and Earth Direction Primary/Secondary Line and Phase Voltages Capacitor Overvoltage Capacitor Unbalance Current Apparent Power and Power Factor Real and Reactive Power Import and Export, Real and Reactive Energy Historical Demand Record Positive Phase Sequence (PPS) Voltage & Current Negative Phase Sequence (NPS) Voltage & Current Zero Phase Sequence (ZPS) Voltage Frequency Harmonic currents up to 15th and Total Harmonic Distortion Binary Input/Output status Trip circuit healthy/failure Time and date Starters Fault records Event records Circuit breaker trip counters I2t summation for contact wear
4 CT 3 Binary Inputs 5 Binary Outputs 4 CT 6 Binary Inputs 8 Binary Outputs 4 CT 3 VT 3 Binary Inputs 5 Binary Outputs 4 CT 3 VT 6 Binary Inputs 8 Binary Outputs
7SR191 Capa Capacitor Bank Protection Relay
Description
User Interface
Hardware
Monitoring Functions
Function Overview
4 Siemens Protection Devices Limited
Standard Communications Ports Communication access to relay functionality is via a front USB port for local PC connection or rear electrical RS485 port for remote connection Additional Optional Communication Ports
2x Electrical RJ45 Ethernet ports 2x LC Fibre Optic Ethernet ports Standard Protocols IEC60870-5-103, Modbus RTU, DNP3.0. User selectable with programmable data points. Optional Protocols
IEC61850 (E6 Case) Ethernet Redundancy Protocols: Standard in all IEC61850 models: PRP (Parallel Redundancy Protocol) RSTP (Rapid Spanning Tree Protocol) HSR (High-availability Seamless Redundancy) Data Up to 1000 event records User configurable fault record duration Waveform records Measurands Commands Time synchronism Viewing and changing settings
The 7SR191 Capa is a numerical protection relay intended for use on shunt connected distribution capacitor banks. It provides a highly comprehensive functional software package with a range of integral application functions aimed at reducing installation, wiring and engineering time. An extensive range of metered values can be viewed on the front LCD or at a remote point via the communication channel. The integrated control feature allows local and remote operation of a single circuit breaker and monitoring of its trip and close circuits. Loss of supply to the capacitor is detected and can be used to disconnect from the network. Automatic blocking of subsequent reconnection until the capacitor has safely discharged is also provided. Distribution capacitor banks are constructed from a large number of individual capacitor units. These units will periodically fail due to the electrical stress applied during normal service. Failure of a single unit is acceptable as the resulting short circuit will be cleared by either operation of fuses, in internally or externally fused arrangements, or simply be coped with by design in unfused and fuseless arrangements. However, the failure of one unit will impose increased stress on remaining units increasing the probability that these units will fail. This will further increase stresses and if not disconnected, could eventually lead to cascading failure of the whole bank. The bank is often split into similar sections, arranged such that the balanced nature
can be used as a basis for early failure detection. Current transformers are typically fitted at suitable locations to allow unbalance current to be measured by protection devices. In addition to this, measurement of the total bank current is measured to detect unbalance between phases caused by capacitor unit failure as well as overload protection and for detection of insulation failure faults such as phase to phase and phase to earth flashover. The 7SR191 provides user configuration settings for operating mode to allow the current inputs to be allocated to the protection functions to cater for all common bank arrangements with a single ordering code. When set in 3 Pole Overcurrent + 1 Pole Unbalance mode, the four current inputs are allocated as three phase current inputs plus one unbalance input. In 1 Pole Overcurrent + 3 Pole Unbalance mode, the four inputs are allocated instead to provide three phase segregated inputs plus a single phase reference input.
FU
NC
TIO
NA
L R
EQ
UIR
EM
EN
T
7S
R1
91
2/7
SR
19
13
3P
OC
+1
P U
B m
od
e *
7S
R1
91
2/7
SR
19
13
1P
OC
+3
P U
B m
od
e *
7S
R1
91
5/7
SR
19
16
3P
OC
+1
P U
B m
od
e *
7S
R1
91
5/7
SR
19
16
1P
OC
+3
P U
B m
od
e *
59C Overvoltage by current integration ■ ■ ■ ■60C Capacitor Unbalance ■ ■ ■ ■37 Undercurrent, Loss of Supply ■ ■ ■ ■Reswitch Blocking ■ ■ ■ ■46MDT Phase Unbalance ■ ■46 Negative Phase Sequence Overcurrent ■ ■
47 Negative Phase Sequence Voltage ■ ■49 Thermal Overload ■ ■ ■ ■50 Instantaneous Overcurrent ■ ■50N Derived Instantaneous Earth Fault ■ ■50BF CB Failure ■ ■ ■ ■
51 Time Delayed Overcurrent ■ ■51N Derived Time Delayed Earth Fault ■ ■27 Undervoltage ■ ■59 Overvoltage ■ ■
59N Neutral Voltage Displacement ■ ■87REF High Impedance Restricted Earth Fault ■ ■67 Directional Overcurrent ■
67N Directional Derived Earth Fault ■
81 Under/Over Frequency ■ ■
CONTROL / MONITOR
51c Cold Load ■ ■ ■ ■
60CTS CT Supervision ■ ■ ■
60VTS VT Supervision ■ ■50BF Circuit breaker Fail ■ ■ ■ ■ Key - ■ - Included as standard * - Mode is selectable by user setting
Application
Function Matrix
Data Storage and Communication
Siemens Protection Devices Limited 5
Typical Unearthed Double Star (DY). fig 1.
Voltage Inputs are optional and provide additional measuring and protection functionality as shown
50N(x4)
60CTS
60C
51c
87 REF
74TCS(x3) (x3)
74CCS
27/59(x4)
60VTS
81 (x4)59IT
49 50(x4)
51(x2)
47 (x2)
59N DT
46IT
47IT (x2) 59N IT
(x2)
46M 50BF
37(x2)
59C DT (x2)
51N (x2)
46DT
60C
(x2)ITDT
59C IT
(x2)
7SR1915/1916 with voltage inputs 3 Pole OC + 1 Pole Unbal.configuration
7SR1912/1913 without voltage inputs
Typical Earthed Double Star (DY). fig 2.
Voltage Inputs are optional and provide additional measuring and protection functionality as shown
50N(x4)
60CTS
60C
51c
87 REF
74TCS(x3) (x3)
74CCS
27/59(x4)
60VTS
81 (x4)59IT
49 50(x4)
51(x2)
47 (x2)
59N DT
46IT
47IT (x2) 59N IT
(x2)
46M 50BF
37(x2)
59C DT (x2)
51N (x2)
46DT
60C
(x2)ITDT
59C IT
(x2)
7SR1915/1916 with voltage inputs 3 Pole OC + 1 Pole Unbal.configuration
7SR1912/1913 without voltage inputs
Typical Earthed Double Star (DY) with segregated unbalance. fig 3.
59N DT 59N IT
27/59(x4)
60VTS 81 (x4)
49 50BF
37(x2)
7SR1915/1916 with voltage inputs 1 Pole OC + 3 Pole Unbal.configuration
Voltage Inputs are optional and provide additional measuring and protection functionality as shown
7SR1912/1913 without voltage inputs74TCS
(x3) (x3)74CCS
59IT 47 (x2) 47IT (x2)
60C
(x2)
59C DT (x2)
60C
(x2)ITDT
59C IT
(x2)
6 Siemens Protection Devices Limited
Typical Single Star. fig 4.
Voltage Inputs are optional and provide additional measuring and protection functionality as shown
50N(x4)
60CTS
60C
51c
87 REF
74TCS(x3) (x3)
74CCS
27/59(x4)
60VTS
81 (x4)59IT
49 50(x4)
51(x2)
47 (x2)
59N DT
46IT
47IT (x2) 59N IT
(x2)
46M 50BF
37(x2)
59C DT (x2)
51N (x2)
46DT
60C
(x2)IT*DT*
59C IT
(x2)
7SR1915/1916 with voltage inputs 3 Pole OC + 1 Pole Unbal.configuration
7SR1912/1913 without voltage inputs
* 60C is not used for this application as no unbalance CT is available
Typical Delta. fig 5.
Voltage Inputs are optional and provide additional measuring and protection functionality as shown
50N(x4)
60CTS
60C
51c
87 REF
74TCS(x3) (x3)
74CCS
27/59(x4)
60VTS
81 (x4)59IT
49 50(x4)
51(x2)
47 (x2)
59N DT
46IT
47IT (x2) 59N IT
(x2)
46M 50BF
37(x2)
59C DT (x2)
51N (x2)
46DT
60C
(x2)ITDT
59C IT
(x2)
7SR1915/1916 with voltage inputs 3 Pole OC + 1 Pole Unbal.configuration
7SR1912/1913 without voltage inputs
Typical H Bridge (Split H). fig 6.
59N DT 59N IT
27/59(x4)
60VTS 81 (x4)
49 50BF
37(x2)
7SR1915/1916 with voltage inputs 1 Pole OC + 3 Pole Unbal.configuration
Voltage Inputs are optional and provide additional measuring and protection functionality as shown
7SR1912/1913 without voltage inputs74TCS
(x3) (x3)74CCS
59IT 47 (x2) 47IT (x2)
59C DT (x2)
59C IT
(x2)
60C
(x2)
60C
(x2)ITDT
Siemens Protection Devices Limited 7
7SR1912/1913 3 Pole OC + 1 Pole Unbal. Config
50N(x4)
51N(x2)
46M46
NPS(x2)
74CCS
IL4
(IUB/REF)
IL1
(IA)
IL2
(IB)
IL3
(IC)
87 REF
50BF
74 TCS
50BF
51c59C (x4)
50BF
51c59C (x4)
50BF
60CTS
51c59C (x4)
60C (x4)
50(x4)
51(x2)
50(x4)
51(x2)
50(x4)
51(x2)
49
49
49
37(x2)
37(x2)
37(x2)
Fig 7. 7SR1912/1913 3 Pole OC + 1 Pole Unbal. Configuration
7SR1912/1913 1 Pole OC + 3 Pole Unbal. Config
60C(x4)
74CCS
IL4
(IREF)
IL1
(IA)
IL2
(IB)
IL3
(IC)
74 TCS
4950BF
37(x2) 51c
59C(x4)
60C(x4)
60C(x4)
50BF
50BF
50BF
Fig 8. 7SR1912/1913 1 Pole OC + 3 Pole Unbal. Configuration
87 REF
46M46
NPS(x2)
37 (x2)
4950BF
VL1
VL2
VL3
IL1
(IA)
60CTS
60VTS
IL4
(IUB/REF)
74CCS
67/50
(x4)
67/51
(x2)
67/50N(x4)
67/51N(x2)
60C(x4)
2759
(x4)
2759
(x4)
2759
(x4)
59N(x2)
47(x4)
50BF
50BF
59C(x4)
51c
81(x4)
7SR1915/1916 3 Pole OC + 1 Pole Unbal. Config
37 (x2)
4950BF
67/50
(x4)
67/51
(x2)
59C(x4)
51c
37 (x2)
4950BF
67/50
(x4)
67/51
(x2)
59C(x4)
51c
74TCS
IL2
(IB)
IL3
(IC)
59 IT
59 IT
59 IT
Fig 9. 7SR1915/1916 3 Pole OC + 1 Pole Unbal. Configuration
VL1
VL2
VL3
IL1
IL2
IL3
I4
74CCS
7SR1915/1916 1 Pole OC + 3 Pole Unbal. Config
74TCS
60C(x4)
50BF
37 (x2)
4950BF
59C(x4)
51c
60C(x4)
50BF
60C(x4)
50BF
2759
(x4)
2759
(x4)
2759
(x4)
59N(x2)
47(x4)
81(x4)
59 IT
59 IT
59 IT
60VTS1P
Fig 10. 7SR1915/1916 1 Pole OC + 3 Pole Unbal. Configuration
Notes 1. The use of some functions are mutually exclusive.
e.g. 60C/87REF 2. Some functions are dependent on the operating
mode selection.
7SR1915/6 Functional Diagrams 7SR1912/3 Functional Diagrams
8 Siemens Protection Devices Limited
27/59 Under/Over Voltage Each element has settings for pickup level, drop-off level and Definite Time Lag (DTL) delays. Operates if voltage exceeds setting for duration of delay. 37 Loss of Supply/Undercurrent Each element has settings for pickup level and Definite Time Lag (DTL) delays. Operates if current falls below setting for duration of delay. Re-switch Blocking If the capacitor is disconnected or otherwise de-energised, automatic blocking of re-energisation can be applied utilising a user selectable timer to allow the capacitor voltage to discharge before re-energisation. Detection of de-energisation can be selected from current level or CB status signals or combinations of both. 46M Phase Unbalance The element has settings for pickup level and DTL delay. The difference in magnitude of the highest and lowest phase current is compared to the average phase current. This can be used to detect that a number of capacitor units have failed in such a pattern that measured unbalance spill current is negligible. 46NPS Negative Phase Sequence Overcurrent Each element has user settings for pickup level and IDMTL or DTL delay, operates if NPS current exceeds setting and delay. NPS current elements can be used to detect that a number of capacitor units have failed in such a pattern that measured unbalance spill current is negligible. 47 Negative Phase Sequence Voltage Each element has settings for pickup level and Definite Time Lag (DTL) delays. Operates if NPS voltage exceeds setting for duration of delay. 49 Thermal Overload The thermal algorithm continuously calculates the present thermal state of the capacitor bank from the measured currents and the previous thermal state thus including long term overload conditions. Alarm outputs are given for thermal overload and thermal capacity. 50BF Circuit Breaker Fail The circuit breaker fail function may be triggered from an internal trip signal or from a binary input. Line currents and earth currents are monitored following a trip signal and an output is issued if any current is still detected, above setting, after a specified time interval. Alternatively, if the trip is from an external protection the circuit breaker position can be used to determine a failure. A second time delay is available to enable another stage to be utilized if required. An input is also available to bypass the time delays when the circuit breaker is known to be faulty.
51c Cold Load Pickup When a capacitor bank is initially energized the connected system may create transient effects which could appear as operating currents at the relay. These conditions can exist for an extended period and must not be interpreted as a fault. To allow optimum setting levels to be applied for normal operation, the cold load pickup feature will apply alternative current settings or protection element inhibits for a limited period. The feature resets when either the circuit breaker has been closed for a settable period, or if the current has reduced beneath a set level for a user set period. 50/51 Phase Fault 50 INST/DTL and 51 IDMTL/DTL elements provide 3 phase overcurrent protection in 3P OC + 1P UB mode, each with independent settings for pickup current, time-multiplier (51) and time-delays. User can select IEC or ANSI time current characteristics. The IDMT stage has a user programmable reset characteristic, either DTL or shaped current ~ time reset characteristic, to improve grading with electromechanical protection. 50N/51N Earth Fault The earth fault current is internally derived from the 3 phase CT inputs in normal operating mode. 50N INST/DTL and 51N IDMTL/DTL elements provide overcurrent protection, each with independent settings for pickup current, time-multiplier (51) and time-delays. User can select IEC or ANSI time current characteristics. The IDMT stage has a user programmable reset characteristic either DTL or shaped current ~ time reset characteristic to improve grading with electromechanical protection.
0.1
1
10
100
1000
1 10 100Current (multiples of setting)
Time(sec)
2 3 4 5 6 8 20 30 40 50 60 80
Long Time Inverse
Normal Inverse
Very Inverse
Extremely Inverse
Fig 11. IEC Overcurrent Curves
Description of Functionality
Siemens Protection Devices Limited 9
0.1
1
10
100
1000
1 10 100Current (multiples of setting)
Time(sec)
2 3 4 5 6 8 20 30 40 50 60 80
Moderately Inverse
Extremely Inverse
Very Inverse
Fig 12. ANSI Overcurrent Curves 59C Overvoltage
The effective applied voltage is calculated from the meas-ured capacitor current by numeric integration techniques such that all harmonic frequency components of the current are correctly incorporated. The capacitor units are rated to withstand 110% of rated voltage continuously. IEC and ANSI standards specify with-stand times for higher voltage levels. These requirements are used to construct an overvoltage withstand curve. Time Multiplier set to default setting = 0.9 is recommended to provide safety margin.
i> (vc>) Standard duration (s) 1.1 infinite
1.15 1,800 lEC 871-1
1.20 300 IEC 871-1
1.30 60 ANSI 18-1980, IEC 871-1
1.40 15 ANSI 18-1980
1.7 1 ANSI 18-1980
2.00 0.3 ANSI 18-1980
2.20 0.12 ANSI 18-1980
Fig 13. Capacitor Curve (Time Multiplier = 1) 59N Neutral Overvoltage Neutral overvoltage can be used to detect unbalance in the capacitor bank in ungrounded arrangements. Operates if the calculated neutral voltage exceeds setting for duration of delay. 60C Capacitor Unbalance
In 3P OC + 1P UB mode, 60C is applied at the 4th current input, typically connected to an unbalance CT. In 1P OC + 3P UB mode, 60C is applied at each of the 3 phase segregated current inputs, typically connected to an unbalance CT. Each element has user settings for pickup level and IDMTL or DTL delay, operates if measured current exceeds setting and delay. The element can be trimmed for phase and magnitude to suit the natural unbalance current and also can be zeroed manually. This calibration is compensated to allows for the switch-off condition 60CTS CT Supervision The relay has two methods of CT supervision. The 7SR1912/3 monitors each phase current input and operates if any one or two inputs fall below the setting. The 7SR1915/6 has the above method and an addition method that considers the presence of negative phase sequence current, without an equivalent level of negative phase sequence voltage, for a user set time as a CT failure. This function is not used in 1 Pole OC + 3 Pole UB mode. Both element types have user operate and delay settings. 60VTS VT Supervision The VT supervision uses a combination of negative phase sequence voltage and negative phase sequence current to detect a VT fuse failure in 3 Pole OC + 1 Pole UB mode. This condition may be alarmed or used to inhibit voltage dependent functions. Element has user operate and delay settings. In1 Pole OC + 3 Pole UB mode, a simpler element using current and voltage magnitudes is provided.
10 Siemens Protection Devices Limited
87REF Restricted Earth Fault The measured earth fault input may be used in a 87REF high impedance restricted earth fault scheme to provide sensitive high speed unit protection. A calculation is required to determine the values of the external series stabilising resistor and non-linear shunt resistor which can be ordered separately. This function is used on single-star arrangements where no unbalance CT is available and is connected to the unused 4th current input. 67/67N Directional Control Phase, earth and sensitive earth fault elements can be directionalised. Each element can be user set to Forward, Reverse, or Non-directional. Directional Phase Fault elements are polarised from quadrature voltage. Derived earth fault elements can be user set to be polarised from residual voltage or negative phase sequence voltage. Measured earth fault elements are polarized from Vo. 74T/CCS Trip & Close Circuit Supervision The trip or close circuit(s) can be monitored via binary inputs. Trip circuit failure raises an HMI alarm and output(s). 81 Under/Overfrequency Each element has settings for pickup level, drop-off level and Definite Time Lag (DTL) delays. Operates if frequency ex-ceeds setting for duration of delay. Programmable Logic The user can map binary inputs, protection elements, LEDs and binary outputs together in a logical scheme. Up to 8 logic equations can be defined using standard logic functions e.g. Timers, AND/OR gates, Inverters and Counters to provide the user required functionality. Each logic equation output can be used for alarm & indication and/or tripping. Virtual Inputs/Outputs There are 8 virtual inputs/outputs to provide internal logical states to assist in the application of the functions. Each virtual I/O can be assigned in the same way as a physical I/O. Circuit Breaker Maintenance Two circuit breaker operations counters are provided to assist with maintenance scheduling. The maintenance counter records the overall number of operations and the delta counter records the number of operations since the last reset. An I2t summation counter provides a measure of the contact wear indicating the total energy interrupted by the circuit breaker contacts. Each counter has a user set target operations count which, when reached, can be mapped to raise alarms/ binary outputs. A CB Trip Time meter is also available, which measures the time between the trip or open command being issued and the auxiliary contacts changing state.
Control Mode The relay has a control menu with access to commonly used command operations. Access to the control commands is restricted by a 4 character control function password. Each command requires a select then execute operation, if the execute operation is not performed within a time window the command is aborted. The following control functions are available: CB Operation
Fig 14. Example of Control Function View
Sequence of event records Up to 1000 events are stored and time tagged to 1ms resolution. Fault Records The last 10 fault records are displayed on the relay fascia and are also available through the communication interface, with time and date of trip, measured quantities and type of fault. The led indications from the time of the fault are also repeated. Waveform recorder The waveform recorder stores analogue data for all poles, the states of protection functions, Binary Inputs, LEDs and Binary Outputs with pre & post trigger data. A record can be triggered from Protection function, Binary input or via data communications. 1 record of 10sec, 2 of 5sec, 5 of 2sec or 10 records of 1 second are stored. The ratio of pre-fault to post fault storage can be set by the user. Demand Metering A record of demand is available. The demand minimum, maximum and average values for currents, frequency and if applicable, voltages and real, reactive and apparent power, over a user selectable period of time, is displayed and available via data communications. Typically this is set as a rolling value for the last 24 hours. Real Time Clock The time and date can be set and are maintained while the relay is de-energised by a back up storage capacitor. The time can be synchronized from a binary input pulse or the data communication channel.
Data Acquisition - Via Communication Interface
Siemens Protection Devices Limited 11
Reydisp Evolution is a Windows based software tool, providing the means for the user to apply settings, interrogate settings and retrieve events and disturbance waveforms from the device and is common to the entire range of Reyrolle protection relays.
Fig 15. Typical Reydisp Evolution Screenshot Language Editor The Language editor software gives the user the ability to customize the text displayed in the relays, Menu structure and instrumentation views. The tool allows a language file to be created and transferred to the relay also containing Western European characters.
Fig 16. Typical Language Editor Screenshot
Communications Editor To facilitate easier interfacing to a substation the relays default Protocol configuration may be modified using the communication editor software tool. The communication editor is a PC based software package provided within the Reydisp software suite which allows modification of the IEC60870-5-103, DNP 3.0 and MODBUS Protocols.
Fig 17. Typical Communications Editor Screenshot Curve Editor The Curve Editor tool can be used to add user defined characteristics for use by any of the Voltage, Current or Thermal IDMTL elements.
Fig 18. Typical Curve Editor Screenshot
Reydisp Evolution
12 Siemens Protection Devices Limited
Reydisp Manager is a Windows based application which enables configuration of multiple Reyrolle devices. It provides the following features: • Project based handling of all features of multiple devices to allow engineering of IEC61850 projects. • Template based structure allowing offline configuration • Configure and store device settings for all settings groups • Create and edit graphical logic diagrams • Configure data points and options for serial protocols • Configure Language • Configure User Curves • Update device firmware Please refer to the Reydisp Manager User Guide for further information.
Fig 19. Typical Reydisp Manager Screenshot
Fig 20. Typical Settings Editor Screenshot
Fig 21. Typical Reylogic Express graphical logic editor Screenshot
The relay offers a USB serial port as standard on the front of all units. All of the relays functions can be set on a PC using Reydisp Evolution via the USB port. The connection is made with a USB cable and operates with a ‘plug and play’ connection, so no pre-setting of the relay is required. The front port can be switched off or set to use either the DNP3.0, MODBUS-RTU, IEC60870-5-103 and ASCII protocols for testing purposes. A rear RS485 electrical connection is available on all units for system interface connections. An internal terminating resistor is provided, which can be connected into the circuit by adding a wire loop between the relevant terminals.
To Control System
14161820
RS485 Screened twisted pair Rear terminals
141618
RS485 Screened twisted pair
Ext Wire loop to Include line
terminating Res
Fig 22. Typical RS485 connection The rear RS485 can be user selected to be OFF, IEC60870-5-103, MODBUS RTU or DNP3.0 protocol.
IEC 61850 IEC61850 communication is available through an optional EN100 communication module. The EN100 Module can be ordered with either 2x Electrical RJ45 or 2x Fibre optic LC Ethernet ports. Information on IEC61850 functionality can be found in the following 7SR191documents:
Model Implementation Conformance Statement (MICS)
Protocol Implementation Conformance Statement (PICS)
Protocol Implementation Extra Information for Testing (PIXIT)
Ethernet Communications
Serial Communications Reydisp Manager
Siemens Protection Devices Limited 13
The relay is housed in a 4U high size E4 or E6 case with a removable clear plastic fascia cover. The plastic fascia cover can be ordered with or without two push buttons to allow the user to view the settings and instruments without removing the cover. Two plastic handles are provided to allow the relay to be withdrawn from its case, contacts in the case ensure that the CT circuits and normally closed contacts remain short circuited when the relay is withdrawn. The rear terminal blocks comprise M4 female terminals for ring crimp wire connections, to provide a secure and reliable termination.
Fig 23. Rear view of E4 relay
Fig.24 Rear view of relay with 2x LC Fibre Optic ports (E6 Case with IEC61850)
User Function
Label
Large LCD
Multi-coloured
LED’sProgrammable
from fascia
Fig 25. User Interface The operator interface is designed to provide a user friendly method of controlling, viewing menus, entering settings and retrieving data from the relay. Five buttons are provided for navigation around the menu structure. LCD A 4 line by 20 character liquid crystal display with power save operation indicates the relay identifier, settings, instrumentation, fault data and control commands. Up to 6 user programmable general alarms can be configured to display your own indications on the LCD. LEDs A green steadily illuminated LED indicates the ‘Protection Healthy’ condition. 9 user programmable LEDs are available eliminating the need for expensive panel mounted pilot lights and associated wiring. Each LED is tri-colour (red, green, yellow) allowing for clear indication of the associated function’s state and has a label insert for identification. Relay Information The device is identified by the rating label on the fascia. The user can also give the device its own identity by editing the ‘Relay Identifier’ displayed on the LCD or space is provided to place a slip in label giving the relays function.
User Interface Construction
14 Siemens Protection Devices Limited
For full technical data refer to the Performance Specification Section of the Technical Manual.
Current Inputs
Quantity 4 Rated Current In 1/5A Measuring Range 80 x In Instrumentation ≥ 0.1xIn ±1% In Frequency 50/60Hz Thermal Withstand: Continuous 1 Second 1 Cycle
4 x In 100A (1A) 350A (5A) 700A (1A) 2500A (5A)
Burden @ In ≤0.02VA (1A phase and Earth element) ≤0.2VA (5A phase and earth element)
Voltage Inputs (optional)
Quantity 3, ph-ph or ph-n Nominal 40…160 Vrms Operating Range 0… 200 Vrms Instrumentation ≥ 0.8xVn ±1% Vn Burden @ 110V ≤ 0.06 VA Overvoltage Withstand 300 Vrms
Auxiliary Supply
Rated DC Voltage 110/125/220/250V
Operating range 64 to 300V 24/48/60V Operating range 18 to 72V
Allowable superimposed ac component
12% of DC voltage
Rated AC Voltage 115 V rms 50/60Hz Range 92 to 138 V rms AC 50/60Hz ±5%
Power Consumption:
E4 Min (DC) E4 Max (DC)
3.9W 8W
E4 Min (AC) E4 Max (AC)
9VA 0.5PF 16VA 0.5PF
E6 Min (DC) E6 Max (DC)
6.4W 10.5W
E6 Min (AC) E6 Max (AC)
14.5VA 0.5PF 21.5VA 0.5PF
Allowable breaks/dips in supply (collapse to zero)
DC 50ms AC 2.5/3 cycles
@50/60Hz
Binary Inputs
Number 3 or 6
Operating Voltage 19V dc DC Range 17 to 320V dc AC Range 92 to 138 VRMSAC
88V dc Range 70 to 320V dc
Maximum dc current for operation
1.5mA
Maximum peak ac current for operation
1.5mA
Pick Up Delay User Selectable 0 to 14,400,000ms (up to 4 hours)
Drop Off Delay User Selectable 0 to 14,400,000ms (up to 4 hours)
For AC operation the BI pick-up delay should be set to 0ms and the drop-off delay to 20ms. Binary Outputs
Number 5 or 8
(3 change over contacts) Operating Voltage Voltage Free Operating Mode User selectable - Self or
Hand/Electrical Reset or pulsed. Operating Time from Energizing Binary Input
<20ms
Making Capacity: Carry continuously Make and carry (L/R ≤40 ms and V ≤300 V)
5A ac or dc 20A ac or dc for 0.5s 30A ac or dc for 0.2s
Breaking Capacity ( ≤ 5 A and ≤ 300 V): AC Resistive AC Inductive DC Resistive DC Inductive
1250 VA 250 VA at p.f. ≤ 0.4 75 W 30 W at L/R ≤ 40ms 50 W at L/R ≤ 10ms
Housing E4 or E6 (see dimension
drawing) Indication 20 Character 4 line Display
Relay Healthy LED 9 Tri Coloured User Programmable Self or Hand Reset LED’s
With-drawable Element Yes User Interface 5 Navigation Keys Weight Typical 3.2kg E4 case,
4.15 kg E6 case. Additional Transport packaging: add 0.4kg
Unit Design
Inputs and Outputs
Technical Data
Siemens Protection Devices Limited 15
Communication Port Front USB Type B
Rear RS485 2 wire electrical
IEC61850 optional ports: 2x Electrical RJ45 Ethernet 2x LC Fibre Optic Ethernet
Protocols IEC60870-5-103
MODBUS RTU (Serial)
DNP3.0 O (Serial)
IEC61850 - optional
Fibre Optic Ethernet Data Communication Interface (IEC 61850 Option)
EN100 Fibre Optic Data Communication Interface (IEC 61850 Option) Physical
Fibre-optic
Connectors Duplex LC 100BaseF in acc. With IEEE802.3
Recommended fibre 62.5/125 µm glass fibre with Duplex-LC connector
Transmission Speed 100 MBits/s
Optical Wavelength 1300 nm
Bridgeable distance 2 km
EN100 Electrical Ethernet Data Communication Interface (IEC 61850 Option) Physical
Electrical
Connectors RJ45 100BaseT in acc. With IEEE802.3
Transmission Speed 100 MBits/s
Test Voltage (with regard to socket)
500 VAC 50 Hz
Bridgeable distance 20m
Fault Record 10 Waveform Record 10 x 1sec
2 x 5sec 5 x 2sec 1 x 10sec Pre trigger 10…90%
Events 1000 1ms Resolution
Vibration (Sinusoidal)
IEC 60255-21-1 Class I Type Level Variation Vibration response 0.5 gn ≤ 5 % Vibration response 1.0 gn ≤ 5 %
Shock and Bump
IEC 60255-21-2 Class I Type Level Variation Shock response 5 gn, 11 ms ≤ 5 % Shock withstand 15 gn, 11 ms ≤ 5 % Bump test 10 gn, 16 ms ≤ 5 %
Seismic
IEC 60255-21-3 Class I Type Level Variation
Seismic response
X-plane - 3.5mm displacement below crossover freq (8-9Hz) 1gn above. Y-plane – 1.5mm displacement below crossover freq (8-9Hz) 0.5gn above.
≤ 5 %
Mechanical Classification
Durability >106 operations
Data Communication Interface Mechanical Tests
Data Storage
16 Siemens Protection Devices Limited
Insulation
IEC 60255-5 Type Level
Between any terminal and earth
2.5 kV AC RMS for 1 min
Between independent circuits
2.5 kV AC RMS for 1 min
Across normally open contacts
1.0 kV AC RMS for 1 min
High Frequency Disturbance
IEC 60255-22-1 Class III Type Level Variation Case, Aux Power & I/O. Common mode
2.5kV ≤ 10%
Case, Aux Power & I/O. Transverse mode
1.0kV ≤ 10%
RS485 Comms 1.0kV No data loss Electrostatic Discharge
IEC 60255-22-2 Class IV Type Level Variation Contact discharge 8.0 kV ≤ 5 %
Electrical Fast Transient / Burst Immunity IEC 60255-22-4 Class A (2002) Type Level Variation Case, Aux Power & I/O 4kV ≤ 10 % RS485 Comms 2.0kV No data loss
Surge Immunity IEC 60255-22-5; IEC 61000-4-5 Type Level Variation Analog Inputs. Line to Earth
4.0 kV ≤ 10 %
Case, Aux Power & I/O. Line to Earth
2.0 kV ≤ 10 %
RS485 Comms port Line to Earth
1.0 kV
No Data Loss
Analog Inputs. Line to Line
1.0 kV ≤ 10 %
Case, Aux Power & I/O. Line to Line
1.0 kV* ≤ 10 %
*Note 50ms DTL pick up delay applied to binary inputs Conducted Radio Frequency Interference
IEC 60255-22-6 Type Level Variation 0.15 to 80 MHz 10 V ≤ 5 %
Radiated Radio Frequency
IEC 60255-25 Type Limits at 10 m, Quasi-peak 30 to 230 MHz 40 dB(µV/m) 230 to 10000 MHz 47 dB(µV/m)
Conducted Radio Frequency
Type Limits
Quasi-peak Average 0.15 to 0.5 MHz 79 dB(µV) 66 dB(µV/m) 0.5 to 30 MHz 73 dB(µV) 60 dB(µV/m)
Radiated Immunity
IEC 60255-22-3 Class III Type Level 80 MHz to 1000 MHz Sweep 10 V/m 1.4GHz to 2.7GHz Sweep 10V/m 80,160,380,450,900,1850, 2150 MHz Spot
10V/m
Magnetic Field with Power Frequency IEC 61000-4-8, Class V Type Level 100A/m (0.126mT) continuous 50Hz 1000A/m (1.26mT) for 3s
Temperature
IEC 60068-2-1/2 Operating Range -10 °C to +55 °C Storage range -25 °C to +70 °C
Humidity
IEC 60068-2-78 Operational test 56 days at 40 °C and 93 %
relative humidity IP Ratings IEC 60529 Type Level
Installed with cover IP 51 from front of relay
Installed with cover removed IP 20 from front of relay
Environmental Tests
Electrical Tests
Siemens Protection Devices Limited 17
27/59 Under/Over Voltage
Number of Elements 4 Under or Over Operate Any phase or All phases Voltage Guard 1 to 200V Setting Range Vs 5 to 200V Hysteresis Setting 0 to 80% Vs Operate Level 100% Vs, ±1% or ±0.25V Reset Level: Overvoltage Undervoltage
=(100%-hyst)xVop, ±1% or ±0.25V =(100%+hyst)xVop, ±1% or±0.25V
Delay Setting td 0.00 to 14400s Basic Operate Time : 0 to 1.1xVs 0 to 2.0xVs 1.1 to 0.5xVs
73ms ±10ms 63ms ±10ms 58ms ±10ms
Operate time following delay.
Tbasic +td , ±1% or ±10ms
Inhibited by Binary or Virtual Input VT Supervision, Voltage Guard
37 Undercurrent
Number of Elements 2 Operate Any phase or ALL Setting Range Is 0.05 to 5.0 x In Operate Level 100% Is, ±5% or ±1%xIn Current Guard 0.05 to 5.0 x In Delay Setting td 0.00 to 14400s Basic Operate Time: 1.1 to 0.5xIn
35ms ±10ms
Operate time following delay.
Tbasic +td , ±1% or ±10ms
Overshoot Time < 40ms Inhibited by Binary or Virtual Input, Guard
46MDT Phase Unbalance
Number of Elements 1 Setting Range Ss 0.01 to 1.0 Operate Level 100% Ss, ±5% for Imean ≥0.1xIn Delay Setting td 0.00 to 14400s Basic Operate Time 0.01 to 1
95ms ±10ms
Operate time following delay.
Tbasic +td , ±1% or ±10ms
Inhibited by Binary or Virtual Input 46 Negative Phase Sequence Overcurrent
Number of Elements DT & IT DT Setting Range Is 0.05,0.10…4.0 x In DT Operate Level 100% Is, ±5% or ±1%xIn DT Delay Setting td 0.00 to 14400s DT Basic Operate Time 0 to 2 xIs 0 to 5 xIs
40ms ±10ms 30ms ±10ms
DT Operate time following delay.
Tbasic +td , ±1% or ±10ms
IT Char Setting IEC NI,VI,EI,LTI ANSI MI,VI,EI & DTL
IT Setting Range 0.05 to 2.5 Tm Time Multiplier 0.025 to 100 Char Operate Level 105% Is, ±4% or ±1%In Overshoot Time < 40ms Inhibited by Binary or Virtual Input
47 Negative Phase Sequence Overvoltage
Number of Elements 2xDT & 2xIT Setting Range Vs 1 to 90V DT Hysteresis Setting 0 to 80% Operate Level 100% Vs, ±2% or ±0.5V DT Delay Setting td 0.00 to14400s Basic Operate Time 0V to 1.5xVs 0V to 10xVs
80ms ±20ms 55ms ±20ms
DT Operate time following delay.
Tbasic +td , ±2% or ±20ms
IT Char Setting IDMTL, DTL IT Tm Time Multiplier 0.025 to 100 IT Char Operate Level 100% Is, ±2% or ±0.5V Overshoot Time < 40ms Inhibited by Binary or Virtual Input
49 Thermal Overload Operate levels Operate and Alarm Setting Range Is 0.10 to 3.0 x In Operate Level 100% Is, ±5% or ±1%xIn Time Constant Setting 1 to 1000min Operate time
( )
×⋅
⋅×= 22
22
B
p
IkIII
Int τ
±5% absolute or ±100ms where Ip = prior current
Alarm Level Disabled, 50,51…100% Inhibited by Binary or Virtual Input
50 (67) Instantaneous & DTL OC&EF (Directional)
Operation 7SR1915/6 only
Non directional, Forward or reverse
Elements Phase (50)& Derived Earth (50N) Number of Elements
4 x OC 4 x Derived EF
Operating Current RMS or Fundamental frequency Setting Range Is
0.05 to 50 x In
Time Delay 0.00 to 14400s Operate Level 100% Is, ±5% or ±1%xIn Operate time: 50 50N
0 to 2xIs – 35ms, ±10ms, 0 to 5xIs – 25ms, ±10ms 0 to 2xIs – 40ms, ±10ms, 0 to 5xIs – 30ms, ±10ms
Operate time following delay
Tbasic +td , ±1% or ±10ms
Inhibited by Binary or Virtual Input VT Supervision
Performance
18 Siemens Protection Devices Limited
51(67) Time Delayed OC&EF (Directional)
Operation – 7SR1915/6 only
Non directional, Forward or reverse
Elements Phase & Derived Earth Number of Elements
2 x OC 2 x Derived EF
Operating Current RMS or Fundamental frequency Characteristic IEC NI,VI,EI,LTI ANSI MI,VI,EI &
DTL Setting Range Is 0.05 to 2.5 x In Time Multiplier 0.025 to 100 Time Delay 0,0.01… 20s Operate Level 105% Is, ±4% or ±1%xIn Minimum Operate time IEC ANSI
[ ] TmKtIsIop ×
−=
1α
[ ] TmBAt PIsIop ×
+
−=
1
± 5 % absolute or ± 30 ms Follower Delay 0 - 20s Reset ANSI decaying, 0 – 60s Inhibited by Binary or Virtual Input
VT Supervision 50BF Circuit Breaker Fail
Operation Current check - Phase and
Measured I4 with independent settings, Mechanical Trip, CB Faulty Monitor
Setting Range Is 0.05 to 2.0 x In 2 Stage Time Delays Timer 1 - 20 to 60000ms
Timer 2 - 20 to 60000ms Operate Level 100% Is, ±5% or ±1%xIn Disengaging time < 20ms Operate time following delay
Tcbf ±1% or ±2ms
Triggered by Any function mapped as trip contact.
Inhibited by Binary/Virtual Input Timer By pass Yes, 50BF CB Faulty Input
59IT Time Delayed Phase Overvoltage
Number of Elements 1 IT Char Setting IDMTL, Capacitor & DTL IT Setting Range 1 to 100V Tm Time Multiplier(IDMT)
0.1 to 140
Delay (DTL) 0 to 20s Operate time IDMTL Capacitor DTL
[ ] 1−=
VsVopMt
, ± 5 % or ± 65 ms.
See Fig. 13 above, ± 5 % or ± 65 ms.
td, ± 1 % or ± 40ms
Reset 0 to 60s Char Operate Level 105% Vs, ±2% or ±0.5V Inhibited by Binary or Virtual Input
59C Capacitor Overvoltage
Number of Elements 2xDT & 2xIT Capacitor Rated Current, equivalent to Vcr
0.1 to 5 xIn
Setting Range Is 80 to 150% Vcr DT Operate Level 100% Vs, ±2% or ±0.5V DT Delay Setting td 0.00 to 14400s DT Basic Operate Time 0 to 2 xVs 0 to 5 xVs
50ms ±10ms 45ms ±10ms
DT Operate time following delay.
Tbasic +td , ±1% or ±20ms
IT Char Setting Capacitor, IDMTL, DTL IT Setting Range 80 to 150% Vcr IT Tm Time Multiplier 0.025 to 1.6 IT Char Operate Level 100% Is, ±2% or ±0.5V Operate time IDMTL Capacitor DTL
[ ] 1−=
VsVopMt
, ± 5 % or ± 65 ms.
See Fig. 13 above, ± 5 % or ± 65 ms. td, ± 1 % or ± 50ms
Overshoot Time < 40ms Inhibited by Binary or Virtual Input
59N Neutral Voltage Displacement
Number of Elements DT & IT DT Setting Range Is 1 to 100V DT Operate Level 100% Vs, ±2% or ±0.5V DT Delay Setting td 0 to 14400s DT Basic Operate Time 0V to 1.5 x Vs 0V to 10 x Vs
76ms ±20ms 63ms ±20ms
DT Operate time following delay.
Tbasic +td , ±1% or ±20ms
IT Char Setting IDMTL & DTL IT Setting Range 1 to 100V Tm Time Multiplier(IDMT)
0.1 to 140
Delay (DTL) 0 to 20s Operate time IDMTL
[ ] 1−=
VsVopMt
, ± 5 % or ± 65 ms.
Reset IEC/ANSI Decaying, 0 to 60s Char Operate Level 105% Vs, ±2% or ±0.5V Inhibited by Binary or Virtual Input
Siemens Protection Devices Limited 19
60C Capacitor Unbalance
Number of Elements DT & IT DT Setting Range Is 0.01 to 2.0 x In DT Operate Level 100% Is, ±5% or ±1%xIn DT Delay Setting td 0.00 to 14400s DT Basic Operate Time 0 to 2 xIs 0 to 5 xIs
50ms ±10ms 40ms ±10ms
DT Operate time following delay.
Tbasic +td , ±1% or ±10ms
IT Char Setting DTL & User Specified IT Setting Range 0.01 to 2 Tm Time Multiplier 0.025 to 100 Char Operate Level 105% Is, ±4% or ±1%In Overshoot Time < 40ms Inhibited by Binary or Virtual Input
60 Supervision CT 7SR1912/3 Current
7SR1915/6 Current or Vnps & Inps
VT 7SR1915/6 nps/zps 87REF Restricted Earth Fault
Setting Range 0.05 to 0.95 xIn Operate Level 100% Is, ±5% or ±1%xIn Time Delay 0 to 60s Basic Operate Time 0 to 2 xIs 40ms ±10ms
0 to 5 xIs 30ms ±10ms Inhibited by Binary or Virtual Input
74T/CC Trip/Close Circuit Supervision
Number of supervisable circuits
3 x Trip and 3 x Close
Number of BI’s Required 1 or 2 per function 81 Under/Over Frequency
Number of Elements 4 Under or Over Under Voltage Guard Yes/No Setting Range Hz 43 to 57Hz (50Hz)
53 to 68Hz (60Hz) Hysteresis Setting 0 to 2% Operate Level 100% Fs ±10mHz Operate Time Typical <150ms Vs Operate Delay 0 to 14400s
Reswitch Blocking
Operation UC, CB position,
UC&CB, UC or CB Blocking time 0 to 60000s Setting Range Is 0.05 to 5.0 x In Operate Level 100% Is, ±5% or ±1%xIn Delay Setting td 0.00 to 14400s Basic Operate Time: 1.1 to 0.5xIn
50ms ±10ms
Operate time following delay.
Tbasic +td , ±1% or ±10ms
CB Maintenance Trip Counter Total & Delta
0…10000 I2t Alarm 10…100000
Control Functions
CB Open/Close EF IN/OUT Relay Mode Local/Remote/Local or Remote Reset LED’s & O/P’s
20 Siemens Protection Devices Limited
E4PANEL CUT-
OUT168
78
98.5
159
10.25
SIDE VIEW
31 216.5
25mm MIN CLEARANCE FOR TERMINAL WIRING
FRONT VIEW
103.5
177
151.
5
11Case Earthconnection
Typical when fitted
Diameter 3.6 - 4 holes (see note)
NOTE:THE 3.6 HOLES ARE FOR M4 THREAD FORMING (TRILOBULAR) SCREWS. THESE ARE SUPPLIED AS STANDARD AND ARE SUITABLE FOR USE IN FERROUS / ALUMINIUM PANELS 1.6mm THICK AND ABOVE. FOR OTHER PANELS, HOLES TO BE M4 CLEARANCE (TYPICALLY 4.5 DIAMETER) AND RELAYS MOUNTED USING M4 MACHINE SCREWS, NUTS AND LOCKWASHERS (SUPPLIED IN PANEL FIXING KIT).
Fig 26. E4 Case overall dimensions and panel drilling details (all dimensions are in mm)
TOP VIEW
FRONT
NOTE:THE 3.6 HOLES ARE FOR M4 THREAD FORMING (TRILOBULAR) SCREWS. THESE ARE SUPPLIED AS STANDARD AND ARE SUITABLE FOR USE IN FERROUS / ALUMINIUM PANELS 1.6mm THICK AND ABOVE. FOR OTHER PANELS, HOLES TO BE M4 CLEARANCE (TYPICALLY 4.5 DIAMETER) AND RELAYS MOUNTED USING M4 MACHINE SCREWS, NUTS AND LOCKWASHERS (SUPPLIED IN PANEL FIXING KIT).
PANEL CUT-OUT168
130
150
159
10
Diameter 3.6 - 4 holes (see note)
FRONT VIEW
155.5
177
SIDE VIEW
31 216.511Case Earthconnection
Typical when fitted
MINIMUM CLEARANCES:25mm FOR TERMINAL WIRING75mm FOR ETHERNET COMMS MODULE
151.
5
Fig.27 E6 Case overall dimensions and panel drilling details (all dimensions are in mm)
Case Dimensions
Siemens Protection Devices Limited 21
DataComms
(optional)
BO 1
GND.
BI 1
A
RS4
85GND
B
Term.
+ve
-ve
+ve
-ve
IL1
22
24
28
2
4
BI 2+ve
-ve
6
8
BI 3+ve
-ve
10
12
14
16
18
20
IL2
IL3
IL4
25
26
27
28
BO 2 6
5
4
1
2
3
BO 38
7
BO 410
9
BO 512
11
1A
5A
13
14
15
16
1A
5A
17
18
19
20
1A
5A
21
22
23
24
1A
5A
AB
1 2
27 28
1 2
27 28
A
B
Shows contacts internal to relay case assembly.Contacts close when the relay chassis is withdrawn from case
NOTES
BI = Binary InputBO = Binary Output
Rear ViewArrangement of terminals and modules
BI 4+ve 3
BI 5+ve 5
BI 6
+ve
-ve
7
1
BO 7
11
13
BO 8 15
9
BO 6
Fig28. Diagram showing 7SR1913 relay with 4 CT inputs, 6 binary inputs and 8 binary outputs.
7SR1912/1913 Connection Diagram
22 Siemens Protection Devices Limited
DataComms
(optional)
BO 1
GND.
BI 1
A
RS4
85GND
B
Term.
+ve
-ve
+ve
-ve
IL1
22
24
28
2
4
BI 2+ve
-ve
6
8
BI 3+ve
-ve
10
12
14
16
18
20
IL2
IL3
IL4
25
26
27
28
BI 4+ve 3
BI 5+ve 5
BI 6
+ve
-ve
7
1
BO 2 6
5
4
1
2
3
BO 38
7
BO 7
11
13
BO 8 15
9
BO 410
9
BO 512
11
1A
5A
13
14
15
16
1A
5A
17
18
19
20
1A
5A
21
22
23
24
1A
5A
AB
1 2
27 28
1 2
27 28
A
BO 6
V117
19
V221
23
V325
27
Rear ViewArrangement of terminals and modules
Shows contacts internal to relay case assembly.Contacts close when the relay chassis is withdrawn from case
NOTES
BI = Binary InputBO = Binary Output
B
SeeRelay
VoltageConfig.Setting
Fig29. Diagram showing 7SR1916 relay with 4 CT inputs, 3 VT inputs, 6 binary inputs and 8 binary outputs.
7SR1915/1916 Connection Diagram
Siemens Protection Devices Limited 23
Product description Variants Order No. Capacitor Protection 7 S R 1 9 1 - 1 A - C A 0 Capacitor Bank protection relay
Protection Product
Miscellaneous Protection 9
Capacitor Protection 1
Case I/O and Fascia 4 CT, 3 Binary Inputs / 5 Binary Outputs, 10 LEDs 2 4 CT, 6 Binary Inputs / 8 Binary Outputs, 10 LEDs 3 4 CT, 3VT, 3 Binary Inputs / 5 Binary Outputs, 10 LEDs 5 4 CT, 3VT, 6 Binary Inputs / 8 Binary Outputs, 10 LEDs 6 Measuring Input 1/5 A, 50/60Hz1), 40-160V2) 1
Auxiliary voltage 80 to 250V DC / 115V AC, binary input threshold 19V DC G 80 to 250V DC, binary input threshold 88V DC H 24 to 60V DC, binary input threshold 19V DC J
Communication Interface Standard version – included in all models, USB front port, RS485 rear port (E4 case) 3) 1 2 Standard version - plus additional rear electrical Ethernet RJ45 (x2) (E6 Case) 3) 7 7 Standard version - plus additional rear optical Ethernet duplex (x2) (E6 Case) 3) 8 7
Protocol IEC 60870-5-103, Modbus RTU and DNP3 (user selectable) 2 IEC 60870-5-103, Modbus RTU, DNP3 and IEC 61850. (user selectable settings) 7
Relay Cover Standard Version – No Push Buttons 1 Push Buttons – Down and Right Arrows 2
Protection Function Packages Standard version C
37 Undercurrent 46M Phase unbalance 46 Negative phase sequence overcurrent 49 Thermal overload 50 Instantaneous phase fault overcurrent 50BF Circuit breaker fail 50N Instantaneous earth fault 51 Time delayed phase fault overcurrent 51c Cold load pickup 51N Time delayed earth fault 59C Overvoltage by current integration 60C Unbalance Overcurrent 60CTS CT supervision 87REF High Impedance REF 74T/CCS Trip & Close circuit supervision Re-energisation Blocking Programmable Logic
For variants with 3 x VT inputs, as above plus: 27/59 Under/overvoltage 47 Negative phase sequence voltage 59N Neutral voltage displacement 60VTS VT Supervision 67/50 Directional instantaneous phase fault overcurrent 67/50N Directional instantaneous earth fault 67/51 Directional time delayed phase fault overcurrent 67/51N Directional time delayed earth fault 81U/0 Under/Over Frequency Additional Functionality No Additional Functionality A
1) 4CT is configured by user setting as: 3PF + 1 Unbalance OR 1PF +3 Unbalance 2) Voltage rating applies to models with optional VT inputs only. 3) E4 case is standard, E6 case is required if IEC61850 option fitted
Ordering Information – 7SR191 Capa Capacitor Bank Protection
24 Siemens Protection Devices Limited
www. siemens.com/energy
Published by and copyright © 2016: Siemens Protection Devices Limited
P.O. Box 8
North Farm Road
Hebburn
Tyne & Wear
NE31 1TZ
United Kingdom
Phone: +44 (0)191 401 7901
Fax: +44 (0)191 401 5575
E-mail: marketing.spdl.gb@siemens.com
EMEA- C10036-00-76GB
November 2016
For enquires please contact our Customer Support Center
Phone: +49 180/524 8437 (24hrs)
Fax: +49 180/524 24 71
E-mail: support.ic@siemens.com
www.siemens.com/protection
Subject to change without notice, Printed in the UK.